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Seismic Waves
and the Slinky: A
Guide For Teachers(v.2.3, December, 2000; last
updated March, 2006)
Prof. Lawrence W. Braile
Department of Earth andAtmospheric Sciences
Purdue UniversityWest Lafayette, IN [email protected]/~braile
Objectives: This teaching guide is designed to introduce the concepts of waves and seismic wavesthat propagate within the Earth, and to provide ideas and suggestions for how to teach about seismicwaves. The guide provides information on the types and properties of seismic waves and instructionsfor using some simple materials especially the slinky to effectively demonstrate seismic wavecharacteristics and wave propagation. Most of the activities described in the guide are useful both asdemonstrations for the teacher and as exploratory activities for students. With several regular metal
slinkys, and the modified slinky demonstrations described in this teaching guide, one can involve anentire class in observation of the demonstrations and experimenting with the slinkys in small groups.For activities that involve several people, such as the 5-slinky and human wave demonstrations, it isconvenient to repeat the demonstrations with different groups of students so that each person willhave the opportunity to observe the demonstration and to participate in it.
Waves: Waves consist of a disturbance in materials (media), that carry energy and propagate.However, the material that the wave propagates in generally does not move with the wave. Themovement of the material is generally confined to small motions, called particle motion, of thematerial as the wave passes. After the wave has passed, the material usually looks just like it didbefore the wave, and, is in the same location as before the wave. (Near the source of a strong
disturbance, such as a large explosion or earthquake, the wave-generated deformation can be largeenough to cause permanent deformation which will be visible as cracks, fault offsets, anddisplacements of the ground after the disturbance has passed.) A source of energy creates the initialdisturbance (or continuously generates a disturbance) and the resulting waves propagate (travel) outfrom the disturbance. Because there is finite energy in a confined or short-duration disturbance, thewaves generated by such a source will spread out during propagation and become smaller (attenuate)
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with distance away from the source or with time after the initial source, and thus, will eventually dieout.
Waves are often represented mathematically and in graphs as sine waves (or combinations or sums ofsine waves) as shown in Figure 1. The vertical axis on this plot represents the temporary motion
(such as displacement amplitude A) of the propagating wave at a given time or location as the wavepasses. The characteristics or properties of the wave amplitude, wavelength, peaks, etc. areillustrated in Figure 1.
Wavelength, (or Period, T)
Amplitu
de,
A
Distance, x (or Time, t)
Properties of a sine wave: y = Asin 2ft
Peak
Trough
Frequency, f = 1/T Figure 1. Properties of a sine
wave. The horizontal axis
displays time or distance and
the vertical axis displays
amplitude as a function of
time or distance. Amplitude
can represent any type ormeasure of motion for any
direction. Seismic wave
motion is commonly displayed
with a similar plot, and
sometimes the wave itself
looks very similar to the sine
wave shown here.
Additional information on the properties of waves can be found in Bolt (1993, p. 29-30) orRutherford and Bachmeyer (1995). Sometimes the actual wave looks very much like therepresentation in the graph (Figure 1). Examples are water waves and a type of seismic surfacewaves called Rayleigh waves. Commonly, propagating waves are of relatively short duration andlook similar to truncated sine waves whose amplitudes vary with time.
Waves generated by a short duration disturbance in a small area, such as from an earthquake or aquarry blast, spread outward from the source as a single or a series of wavefronts. The wavefronts atsuccessive times, and corresponding raypaths that show the direction of propagation of the waves, areillustrated in Figure 2. A good model for illustrating wave motion of this type is water waves from apebble dropped in a still pond or pool. The disturbance caused by the pebble hitting the surface of
the water generates waves that propagate outward in expanding, circular wavefronts. Because thereis more energy from dropping a larger pebble, the resulting waves will be larger (and probably ofdifferent wavelength).
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Wav
efro
nt
t0
t1
t2
t3
Raypath
Compressional (P) m otion
Shear (S)motion
Wavefronts and Raypaths in
Seismic Wave Propagation
Source
Perpendi
cular
angle
Figure 2. Wavefronts and raypaths for a
seismic wave propagating from a source.
Three positions (successive times) of theexpanding wavefront are shown. Particle
motions for P (compressional) and S (shear)
waves are also shown. Raypaths are
perpendicular to the wavefronts and indicate
the direction of propagation of the wave. P
waves travel faster than S waves so there will
be separate wavefront representations for the
P and S waves. If the physical properties of
the material through which the waves are
propagating are constant, the wavefronts will
be circular (or spherical in three-dimensions). If the physical properties vary
in the model, the wavefronts will be more
complex shapes.
Waves in Water Experiment: Experiments with water waves in a small wave tank, consisting of arectangular plastic storage box (about 60 to 120 cm long by 40 cm wide by 15 cm high; the exact sizeisnt important); a plastic storage box designed to fit under a bed, available at discount departmentstores such as K-Mart, Wal-Mart and Target, with about 5 cm of water in it, can easily illustrate thecommon properties of water waves (Figure 3). Drops of water from an eyedropper or small sphericalobjects (a table tennis ball, a golf ball, or a small rubber ball works well) dropped onto the surface of
the water are convenient sources. With the wave tank one can demonstrate that: the size (amplitude)of the waves is related to the energy of the source (controlled by the mass and drop height); thewaves expand outward (propagate) in circular wavefronts; the wave height decreases andeventually dies out with distance away from the source (or with time after the source) because ofspreading out of the wave energy over a larger and larger area (or volume); the waves have a speed(velocity) of propagation that can be measured by placing marks every 10 cm on the bottom of thetank and timing the wave with a stopwatch; the waves reflect off the sides of the tank and continuepropagating in a different direction after reflection. About 3-4, small floating flags can be used tomore effectively see the motion of the water as the wave passes. The flags are particularly useful fornoting the relative amplitude of the waves as the degree of shaking of the flags is a visible indicationof the size of the wave. Flags can be made from small pieces (~2x2x1 cm) of closed cell foam,
styrofoam or cork. Place a small piece of tape on a toothpick and stick the toothpick into the foam orcork to create a floating flag (Figure 4) that is sensitive to waves in the water. By placing the flags inthe wavetank at various distances from the source, one can easily observe the time of arrival and therelative amplitudes of the waves. A glass cake pan (Figure 5) can be used as small wave tank on anoverhead projector. Waves generated by dropping drops of water from an eyedropper into about 2cm of water in the tank will be visible on the screen projected from the overhead projector. The
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velocity of propagation, attenuation of wave energy, and reflection of waves are important conceptsfor understanding seismic wave propagation, so experimenting with these wave properties in thewater tank is a very useful exercise. Additional suggestions for experiments with water waves arecontained in Zubrowski (1994).
Figure 3. Large wave tank using a plastic storage container (75 liter "under bed" container).
Distances in cm can be marked on the bottom of the container for convenient measurement of wave
velocity from the distance and travel time. Small floating flags (Figure 4) are useful for identifying
the time and relative amplitude of propagating water waves. The flags are made from small floats(about 2x2x1 cm rectangular blocks of closed cell foam, Styrofoam or cork) with a toothpick and
piece of tape attached. The floating flags are very sensitive to wave motion in the wave tank. In this
sequence of photos, taken every one-half second, one can see the waves propagating outward from
the source. Lines drawn on the bottom of the tank are spaced at 10 cm. A. Source (a table tennis
ball dropped from about 40 cm height) is just ready to hit the water surface. B. (~ 0.5 s after the
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source) Water waves have propagated from the source to about 10 cm distance. A circular
expanding wavefront is visible and the wave height is larger than in the later photos. C. (~ 1.0 s)
The wavefront has propagated to about 20 cm distance and the waves have decreased in amplitude.
D. (~ 1.5 s) The wavefront has propagated to about 30 cm distance. E. (~ 2 s) The wavefront has
propagated to about 40 cm distance and the wave amplitudes have decreased so much that they are
difficult to see in this photo. The small floating flags are sensitive detectors (similar to seismometers)
of the waves. Because the waves have traveled about 40 cm in 2 seconds, the velocity of propagation
is about 20 cm/s or 0.2 m/s.
Bottom of wave tank
Float (~2 x 2 x 1 cm
closed cell foam or
styrofoam)
Nickel
Toothpick
Flag made
with tape
Thread or fish ing line inserted through float
Figure 4. Small floating flags used to help detect
the motion of water waves in a wave tank. The
flags can be "anchored" using a length of thread
and a nickel for a weight. The flags are sensitiveto the motion caused by relatively small waves.
By noting the degree of shaking of the flags, one
can identify (approximately) large, medium and
small (barely detectible) wave action. Be sure
the water surface is calm (and the flags still)
before initiating a water wave experiment.
Figure 5. Small wave tank using a clear glass cake or baking dish. The dish with about 2 cm of
water in it can be placed on an overhead projector so that wave propagation in the water can be seen
on a screen.
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Elasticity: Earth materials are mostly solid rock and are elastic, and thus propagate elastic or seismicwaves in which elastic disturbances (deformation or bending or temporary compression of rocks)travel through the Earth. Elastic materials have the properties that the amount of deformation isproportional to the applied force (such as the stretching of a spring as masses are suspended from thespring), and that the material returns to its original shape after the force is removed (such as thespring returning to its original length after the masses are removed).
Elasticity of a Spring Experiment: An experiment designed to illustrate the elastic characteristicsof a spring is shown in Figure 6. Measurements of the stretching of the spring as masses are addedand removed are given in Table 1 and graphed in Figure 7. In contrast, some materials like mostmetals, are ductile. For example, if one bends a copper wire, it stays bent rather than returning to itsoriginal shape. One can even make a spring out of copper wire by wrapping the wire tightly around acylindrical shaped object, such as a cardboard tube. Repeating the elasticity experiment with thecopper wire spring will result in an elastic behavior (straight line relationships between the stretchingand the amount of mass added) for small mass, and permanent deformation (stretching) for larger
masses (the spring will not return to its original length as masses are removed). Data for the copperwire spring experiment can be tabulated, as in Table 1, and graphed, as in Figure 7. Because thisexperiment produces a very different stretching versus added mass curve, as compared to the regularspring example, it is useful to ask the students before the experiment what they expect the results tolook like and then compare the actual results with their predictions.
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Wood
PVC
Pipe
Mass
SpringLength
of
Spring
Standard
Measuring Elastici ty of a Spri ng
Figure 6. Schematic diagram illustrating mass and spring
apparatus for measuring the elasticity (stretching of the
spring as mass is added) of a spring.
Table 1. Observations of extension of a spring upon adding and removing masses.
Added Mass(g)
Spring Extension (cm)*(adding masses)
Spring Extension (cm)*(removing masses)
0 0.0 0.3
100 3.7 3.6
200 7.7 7.5
300 11.4 11.4
400 15.3 15.1
*Spring extension (stretching) is the length of the spring with mass attached minus the length of the
spring with no mass. Different springs have different spring constants (elasticity) and will display
different amounts of stretching for a given amount of added mass. Many springs are tightly-wound
and require a small amount of force (suspended mass) to begin extending. For these springs, oneshould use the difference between this initial suspended mass and the total mass as the "added mass."
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0 50 100 150 200 250 300 350 4000
2
4
6
8
10
12
14
16
Added Mass (gram s)
Stretching(length-originallengt
h,cm)
Elasticity of a Spring
Add ing mass:
Removing mass:
1. Deformation (stretching) is
proportional to applied force (mass).
2. Spring returns to its original shape
(length) when force is removed.
Figure 7. Graph showing measurements of
elasticity of a spring. Measurements weremade as mass was added and removed. The
stretching of the spring is defined as the
spring length (with added mass) minus the
original length. Note that the extension
versus mass data define a straight line. The
slope of this line is related to the spring
constant or elasticity of the spring. The two
properties that characterize simple elasticity
are described in the figure.
Seismic Waves: Unlike waves in water which are confined to a region very near to the water'ssurface, seismic waves also propagate through the Earth's interior. Because of the elastic propertiesof Earth materials (rocks) and the presence of the Earth's surface, four main types of seismic wavespropagate within the Earth. Compressional (P) and Shear (S) waves propagate through the Earthsinterior and are known as body waves (Figure 8). Loveand Rayleighwaves propagate primarily atand near the Earth's surface and are called surface waves. Wave propagation and particle motioncharacteristics for the P, S, Rayleigh and Love waves are illustrated in Figures 9-12. Furtherinformation and characteristics of these four kinds of seismic waves are given in Table 2.
P- and S- Waves (propagation along raypath)
X
Y
S-wave particle
motion -- perpendicular
to direction of propagation (usually
approxi mately in SV and SH
directions)
Earths surface
* P-wave particle motion -- parallel to direction of
propagation
Source
Seismograph
Z (down)
SV
SH
Figure 8. Raypath from the source to a
particular location on the surface for P-
and S- wave propagation in a material with
variable velocity. P and S particle motion
are shown. Because major boundaries
between different rock types within the
Earth are normally approximately parallel
to the Earth's surface, S-wave particle
motion is commonly in the SV
(perpendicular to the raypath and vertical)
and SH perpendicular to the raypath andhorizontal) directions.
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Figure 9. Perspective view of elastic P-wave propagation through a grid representing a volume of
material. The directions X and Y are parallel to the Earth's surface and the Z direction is depth. T =
0 through T = 3 indicate successive times. The disturbance that is propagated is a compression (grid
lines are closer together) followed by a dilatation or extension (grid lines are farther apart). The
particle motion is in the direction of propagation. The material returns to its original shape after the
wave has passed.
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Figure 10. Perspective view of S-wave propagation through a grid representing a volume of elastic
material. The disturbance that is propagated is an up motion followed by a down motion (the shear
motion could also be directed horizontally or any direction that is perpendicular to the direction of
propagation). The particle motion is perpendicular to the direction of propagation. The material
returns to its original shape after the wave has passed.
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Figure 11. Perspective view of Rayleigh-wave propagation through a grid representing a volume of
elastic material. Rayleigh waves are surface waves. The disturbance that is propagated is, in
general, an elliptical motion which consists of both vertical (shear; perpendicular to the direction of
propagation but in the plane of the raypath) and horizontal (compression; in the direction of
propagation) particle motion. The amplitudes of the Rayleigh wave motion decrease with distance
away from the surface. The material returns to its original shape after the wave has passed.
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Figure 12. Perspective view of Love-wave propagation through a grid representing a volume of
elastic material. Love waves are surface waves. The disturbance that is propagated is horizontal
and perpendicular to the direction of propagation. The amplitudes of the Love wave motion decrease
with distance away from the surface. The material returns to its original shape after the wave has
passed.
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Table 2: Seismic Waves
Type (andnames)
Particle Motion Typical Velocity Other Characteristics
P,Compressional,Primary,Longitudinal
Alternating compressions(pushes) and dilations(pulls) which aredirected in the samedirection as the wave ispropagating (along theraypath); and therefore,perpendicular to thewavefront
VP~ 5 7 km/s intypical Earths crust;
>~ 8 km/s inEarths mantle andcore; 1.5 km/s inwater; 0.3 km/s inair
P motion travels fastest in materials,so the P-wave is the first-arrivingenergy on a seismogram. Generallysmaller and higher frequency than theS and Surface-waves. P waves in aliquid or gas are pressure waves,including sound waves.
S,Shear,Secondary,
Transverse
Alternating transversemotions (perpendicular tothe direction of
propagation, and theraypath); commonlypolarized such thatparticle motion is invertical or horizontalplanes
VS~ 3 4 km/s intypical Earths crust;
>~ 4.5 km/s in
Earths mantle; ~2.5-3.0 km/s in(solid) inner core
S-waves do not travel through fluids,so do not exist in Earths outer core(inferred to be primarily liquid iron) or
in air or water or molten rock(magma). S waves travel slower thanP waves in a solid and, therefore,arrive after the P wave.
L,Love, Surfacewaves, Longwaves
Transverse horizontalmotion, perpendicular tothe direction ofpropagation andgenerally parallel to theEarths surface
VL ~ 2.0 - 4.5 km/sin the Earthdepending onfrequency of thepropagating wave
Love waves exist because of theEarths surface. They are largest atthe surface and decrease in amplitudewith depth. Love waves aredispersive, that is, the wave velocity isdependent on frequency, with low
frequencies normally propagating athigher velocity. Depth of penetrationof the Love waves is also dependenton frequency, with lower frequenciespenetrating to greater depth.
R,Rayleigh, Surfacewaves, Longwaves, Groundroll
Motion is both in thedirection of propagationand perpendicular (in avertical plane), andphased so that themotion is generallyelliptical eitherprograde or retrograde
VR ~ 2.0 - 4.5 km/sin the Earthdepending onfrequency of thepropagating wave
Rayleigh waves are also dispersiveand the amplitudes generally decreasewith depth in the Earth. Appearanceand particle motion are similar towater waves.
Additional illustrations of P, S, Rayleigh and Love waves are contained in Bolt (1993, p. 27 and 37)and in Shearer (1999, p. 32 and 152). Effective animations of P and S waves are contained in theNova video "Earthquake" (1990; about 13 minutes into the program) and of P, S, Rayleigh and Lovewaves in the Discovery Channel video "Living with Violent Earth: We Live on Somewhat Shaky
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Ground" (1989, about 3 minutes into the program) and in the animations and activities available at:http://web.ics.purdue.edu/~braile/edumod/waves/WaveDemo.htm.
Slinky Demonstrations of P and S Waves:The P and S waves have distinctive particle motions(Figures 8, 9, and 10, and Table 2) and travel at different speeds. P and S waves can be demonstratedeffectively with a slinky. For the P or compressional wave, have two people hold the ends of theslinky about 3-4 meters apart. One person should cup his or her hand over the end (the last 3-4 coils)of the slinky and, when the slinky is nearly at rest, hit that hand with the fist of the other hand. Thecompressional disturbance that is transmitted to the slinky will propagate along the slinky to the otherperson. Note that the motion of each coil is either compressional or extensional with the movementparallel to the direction of propagation. Because the other person is holding the slinky firmly, the Pwave will reflect at that end and travel back along the slinky. The propagation and reflection willcontinue until the wave energy dies out. The propagation of the P wave by the slinky is illustrated inFigure 13.
Figure 13. Compressional (P) wave propagation in a slinky. A disturbance at one end results in a
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compression of the coils followed by dilation (extension), and then another compression. With time
(successive times are shown by the diagrams of the slinky at times t1through t6), the disturbance
propagates along the slinky. After the energy passes, the coils of the slinky return to their original,
undisturbed position. The direction of particle motion is in the direction of propagation.
Figure 14. Shear (S) wave propagation in a slinky. A disturbance at one end results in an up motion
of the coils followed by a down motion of the coils. With time (successive times are shown by the
diagrams of the slinky at times t1through t6), the disturbance propagates along the slinky. After the
energy passes, the coils of the slinky return to their original, undisturbed position. The directionof
particle motion is perpendicular (for example, up and down or side to side) to the direction ofpropagation.
Demonstrating the S or Shear wave is performed in a similar fashion except that the person whocreates the shear disturbance does so by moving his or her hand quickly up and then down. Thismotion generates a motion of the coils that is perpendicular to the direction of propagation, which is
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along the slinky. Note that the particle motion is not only perpendicular to the direction of motionbut also in the vertical plane. One can also produce Shear waves with the slinky in which the motionis in the horizontal plane by the person creating the source moving his or her hand quickly left andthen right. The propagation of the S wave by the slinky is illustrated in Figure 14. Notice that,although the motion of the disturbance was purely perpendicular to the direction of propagation (nomotion in the disturbing source was directed along the slinky), the disturbance still propagates awayfrom the source, along the slinky. The reason for this phenomenon (a good challenge question forstudents) is because the material is elastic and the individual coils are connected (like the individualparticles of a solid) and thus transmit their motion to the adjacent coils. As this process continues,the shear disturbance travels along the entire slinky (elastic medium).P and S waves can also be generated in the slinky by an additional method that reinforces the conceptof elasticity and the elastic rebound theory which explains the generation of earthquakes by platetectonic movements (Bolt, 1993, p. 74-77). In this method, for the P wave, one person should slowlygather a few of the end coils of the slinky into his or her hand. This process stores elastic energy inthe coils of the slinky that are compressed (as compared to the other coils in the stretched slinky)similar to the storage of elastic energy in rocks adjacent to a fault that are deformed by plate motions
prior to slip along a fault plane in the elastic rebound process. When a few coils have beencompressed, release them suddenly (holding on to the end coil of the slinky) and a compressionalwave disturbance will propagate along the slinky. This method helps illustrate the concept of theelastic properties of the slinky and the storage of energy in the elastic rebound process. However, thecompressional wave that it generates is not as simple or visible as the wave produced by using a blowof ones fist, so it is suggested that this method be demonstrated after the previously-describedmethod using the fist.
Similarly, using this "elastic rebound" method for the S waves, one person holding the end of thestretched slinky should use their other hand to grab one of the coils about 10-12 coils away from theend of the slinky. Slowly pull on this coil in a direction perpendicular to the direction defined by the
stretched slinky. This process applies a shearing displacement to this end of the slinky and storeselastic energy (strain) in the slinky similar to the storage of strain energy in rocks adjacent to a faultor plate boundary by plate tectonic movements. After the coil has been displaced about 10 cm or so,release it suddenly (similar to the sudden slip along a fault plane in the elastic rebound process) andan S wave disturbance will propagate along the slinky away from the source.
Illustration of Energy Carried by the Waves: The fact that the seismic waves (P or S) thatpropagate along the slinky transmit energy can be illustrated effectively by using a slinky in whichone end (the end opposite the source) has a small wood block attached. The wood block has acardboard model building attached to it as shown in Figures 15 and 16. As P or S wave energythat propagates along the slinky is transmitted to the wood block, the building vibrates. This model is
a good demonstration of what happens when a seismic wave in the Earth reaches the surface andcauses vibrations that are transmitted to houses and other buildings. By generating P, S-vertical andS-horizontal waves that transmit vibration to the model building, one can even observe differences inthe reaction of the building to the different directions of motion of the propagating wave.
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SlinkyWood block
(~9 x 9 x 2 c m)
Holes
(6.3 cm
apart)
Screw and
washer*
8cm
8 cm
8 cm
2 cm8cm
3 cm wide
strips cut from
manila folder
tape
Cardboard houseattached to a slinky toillustrate shaking causedby P- and S-waves
* (#6 x 1/2 in. screws;
3/16 in. washers)
Figure 15. Diagram showing how to attach aslinky to the edge of a small wood block with
screws and washers. A cardboard "building" is
attached with tape to the wood block. The model
building is made from manila folder (or similar)
material and is taped together. The diagram is a
side view of the slinky, wood block and model
building. When seismic waves are propagated
along the slinky, the vibrations of the cardboard
building show that the wave energy is carried by
theslinky and is transmitted to the model building.
Figure 16. Photograph of slinky attached to a small wood block (Figure 15) and cardboard
"house." The slinky could also be attached to the bottom ot the wood block to illustrate P- and S-
waves propagating upwards and shaking the building.
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Wave Propagation in All Directions: An additional demonstration with P and S waves can beperformed with the 5-slinky model. By attaching 5 slinkys to a wood block as shown in Figure 17, 5people can hold the ends of the 5 slinkys (stretched out in different directions to about 3-4 m each).One person holds the wood block and can generate P or S waves (or even a combination of both) byhitting the wood block with a closed fist or causing the block to move quickly up and then down orleft and then right. The purpose of this demonstration is to show that the waves propagate in alldirections in the Earth from the source (not just in the direction of a single slinky). Attaching anadditional slinky (with small pieces of plastic electrical tape) to one of the five slinkys attached tothe wood block makes one slinky into a double length slinky which can be stretched out to 6-8 m.For one of the other four slinkys, have the person holding it collapse about half of the coils and holdthem in his or her hands, forming a half slinky, stretched out about 1 - 2 m. Now when a source iscreated at the wood block, one can see that the waves take different amounts of time to travel thedifferent distances to the ends of the various slinkys. An effective way to demonstrate the differentarrival times is to have the person holding each slinky call out the word "now" when the wave arrivesat their location. The difference in arrival times for the different distances will be obvious from the
sequence of the call of "now." This variation in travel time is similar to what is observed for anearthquake whose waves travel to various seismograph stations that are different distances from thesource (epicenter). Although these two demonstrations with the five slinky model represent fairlysimple concepts, we have found the demonstrations to be very effective with all age groups. In fact,the five slinky demonstrations are often identified as the "favorite" activities of participants.
Wood block
Slinky
Holes,6.3 cm apart
Screw and washer
~ 10 cm
~ 25 cm
Five Slinky P and S Wave Propagation Demonstration
Figure 17. Diagram showing how five slinkys can be attached to the edge of a wood block.Photographs of the five slinky model are shown in Figures 18 and 19. When the slinkys are stretched
out to different positions (five people hold the end of one slinky each) and a P or S wave is generated
at the wood block, the waves propagate out in all directions. The five slinky model can also be used
to show that the travel times to different locations (such as seismograph stations) will be different.
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To demonstrate this effect, wrap a small piece of tape around a coil near the middle of the slinky for
one of the slinkys. Have the person holding that slinky compress all of the coils from the outer end to
the coil with the tape so that only one half of the slinky is extended. Also, attach an additional slinky,
using plastic electrical tape, to the end of one of the slinkys. Have the person holding this double
slinky stand farther away from the wood block so that the double slinky is fully extended. When a P
or S wave is generated at the wood block, the waves that travel along the slinky will arrive at the end
of the half slinky first, then at approximately the same time at the three regular slinkys, and finally,
last at the double length slinky. The difference in travel time will be very noticeable.
Figure 18.
Photographof five slinky
model.
Figure 19. Close-up
view of five slinky
model showing
attachment of slinky
using screws and
washers.
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Human Wave Demonstration P and S Waves in Solids and Liquids: This demonstrationinvolves a class or group in simulating seismic wave propagation in solids and liquids. If you have20 or more people in the group, half can perform the demo while the other half watches; then switchplaces. The concepts that are involved in this demonstration are very dramatically illustrated to theparticipants. Once they have done the human wave activity, they should always remember theproperties of P and S waves propagating in both solids and liquids. Have about 10 people stand at thefront of the room, side by side, with their feet about shoulder width apart. Instruct the group to not betoo rigid or too limp when pushed from the side. They should give with the force that they will feelfrom the person next to them, but not fall over, and then return to their upright position. In otherwords, they should be "elastic". Have a spotter at the end of the line in case the last person beginsto fall. (It is important to stress these instructions to the participants so that the demonstration willwork effectively and so that participants do not fall over as the wave propagates down the line ofpeople.)
To represent wave propagation in a solid, have each person put their arms over the shoulders of theperson next to them (chorus line style; the molecules or "particles" of the solid are tightly
bonded). Push on the person at the end of the line and the deformation (leaning to the side and thenstraightening up) will propagate down the line of people approximating a P wave (Figure 20). Notethat the propagation down the line took some time (there is a velocity for the wave propagation) andthat although each person was briefly subjected to a deformation or disturbance, the individuals didnot move from their original locations. Also, the motion of each person as the wave passed was inthe direction of propagation and that, as the wave passed, the people moved closer togethertemporarily (compression), and then apart (dilation) to return to their original positions.
Figure 20. Human wave demonstration
for the P wave in a solid. Instructorbegins the P wave motion (in this case
from left to right) in the line by pushing
(compressing) on the first person in the
line and then pulling the person back to
an upright position.
For the S wave in a solid, make the first person at the end of the line bend forward at the waist andthen stand up straight. The transverse or shear motion will propagate down the line of people (Figure
21). Again, the wave takes some time to propagate and each person ends up in the same locationwhere they started even though a wave has passed. Also, note that the shear motion of each particleis perpendicular to the direction of propagation. One of the observers can time the P and S wavepropagation in the human wave using a stopwatch. Because the shear wave motion is morecomplicated in the human wave, the S wave will have a slower velocity (greater travel time fromsource to the end of the line of people), similar to seismic waves in a solid.
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Figure 21. Human wave demonstration for the S wave in a solid. The teacher starts the S wave
motion (in this case propagating from right to left) in the line by causing the first person in the line to
bend forward at the waist and then stand up straight.
Next, to represent wave propagation in a liquid, have the people stand shoulder-to-shoulder, withouttheir arms around each other. Push on the shoulder of the end person and a P wave will propagatedown the line. The P wave will have the same characteristics in the liquid as described previously forthe solid. Now, make the person at the end of the line bend forward at the waist a transverse orshear disturbance. However, because the molecules of the liquid are more loosely bound, theshearing motion will not propagate through the liquid (along the line of people). The disturbancedoes not propagate to the next person because the liquid does not support the shearing motion.(Compare pressing your hand down on the surface of a solid such as a table top and on the surface ofwater and moving your hand parallel to the surface. There will be considerable resistance to movingyour hand on the solid. One could even push the entire table horizontally by this shearing motion.
However, there will be virtually no resistance to moving your hand along the surface of the water.)Only the first person in the line the one that is bent over at the waist should move because thepeople are not connected. If the next person bends, sympathetically, not because of the wavepropagating, ask that person if he or she felt, rather than just saw, the wave disturbance, then repeatthe demonstration for S waves in a liquid.
Velocity of Wave Propagation Experiment: Developing an understanding of seismic wavepropagation and of the velocity of propagation of seismic waves in the Earth is aided by makingmeasurements of wave speed and comparing velocities in different materials. For waves that travelan approximately straight line (along a straight raypath), the velocity of propagation is simply thedistance traveled (given in meters or kilometers, for example) divided by the time of travel (or "travel
time") in seconds. Using a stopwatch for measuring time and a meter stick or metric tape formeasuring distance, determine the wave velocity of water waves in the wave tank, the P wave in theslinky, and the P wave in the human wave experiment. Also, determine the velocity of sound in airusing the following method. On a playfield, measure out a distance of about 100 meters. Have oneperson with a stopwatch stand at one end of the 100 meter line. Have another person with a metalgarbage can and a stick stand 100 meters away from the person with the stopwatch. Have the person
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with the stick hit the garbage can so that the instant of contact of the stick with the garbage can isvisible from a distance. The person with the stopwatch should start the stopwatch when the stickstrikes the can and stop it when the sound generated by the stick hitting the can is heard. Themeasured speed of sound will be the distance divided by the travel time measured on the stopwatch.(This measurement assumes that the speed of light is infinite a reasonable approximation as theactual speed of light is about 3 x 108or 300 million meters/second, much faster than the speed ofsound, and that the reaction time for the person operating the stopwatch is about the same for startingthe watch when the can is struck and for stopping the watch when the sound is heard. Themeasurement should be repeated a few times to obtain an estimate of how accurately themeasurement can be made. An average of the time measurements can be used to calculate the soundspeed. The difference between the arrival of a light wave and associated sound is commonly used todetermine how far away a lightning strike is in a thunderstorm. For example, because the speed ofsound in air is about 330 m/s, if the difference in time between seeing a lightning strike and hearingthe associated thunder is 3 seconds, the lightning is 1 km away; similarly, 6 s for 2 km away, etc.)
Make a list of the wave velocities (in m/s) for the water waves, slinky, human wave, and sound wave
in air. (Measured wave speeds should be approximately 0.25-0.5 m/s for water waves in a wave tank,2 m/s for the compressional human wave, 3 m/s for P waves in the slinky, and 330 m/s for soundwaves in air.) Compare these wave velocities with the compressional wave velocity in the Earthwhich varies from about 1000 m/s for unconsolidated materials near the Earth's surface to about14,000 m/s in the Earth's lowermost mantle (1 to 14 km/s). The seismic velocity in solid rocks in theEarth is controlled by rock composition (chemistry), and pressure and temperature conditions, and isfound to be approximately proportional to rock density (density = mass/unit volume; higher densityrocks generally have larger elastic constants resulting in higher seismic velocity). Furtherinformation on seismic velocities and a diagram showing seismic velocity with depth in the Earth isavailable in Bolt (1993, p. 143) and Shearer (1999, p. 3).
Attenuation of Waves: To demonstrate the property of anelasticity, a model with two slinkys can beconstructed. Anelasticity is the absorption of energy during propagation which causes waves toattenuate in addition to the attenuation caused by the energy spreading out (for example, like thespreading of water waves created by dropping a pebble into a pond). This effect is an importantconcept in evaluating earthquake hazards and comparing the hazards in two locations such as thewestern United States and the eastern United States. Seismic waves propagate very efficiently in theeastern United States resulting in damage over a wide area from a large earthquake. In contrast,waves propagating in the western United States are attenuated by absorption of energy to a muchgreater degree. Thus, although earthquakes of a given size occur much more often in the western US,the earthquake hazard in the eastern US is significant because the area of damage (for equivalent
earthquakes) is larger in the eastern US. Attach two slinkys to a 30 cm long piece of one by two(1 by 2 wood trim) using washers and screws (Figure 22) similar to that shown in Figure 15. Forone of the slinkys, place a strip of foam (about a 3 m strip of thick foam 7 cm wide; the 3 m stripcan be pieced together from 2-3 shorter pieces; tape or sew together the strips) in the extended coils.The foam should fit snugly within the coils and will absorb wave energy that is propagated along theslinky.
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Two s linkys u sed to demonstrate v arying effic iency of wave prop agation due to absor ption of energy (anelas ticity )
M etal slinky with strip of foam inside coils
Metal slinky
Two s linkysattached towood block
Wood bl ockswith cardboard build ings
~3 m
Figure 22. Schematic diagram illustrating the construction of a model using two slinkys (one with afoam strip inside the coils of the slinky) that can be used to demonstrate the concept of absorption of
energy by material during propagation (anelasticity). A photo of the slinky model for demonstrating
absorption is shown in Figure 23.
Figure 23. Slinky model used to demonstrate attenuation of waves by absorption of energy.
Small wood blocks and model buildings (Figure 15) can be attached to the free ends of both theregular slinky and the foam-lined slinky so that the wave energy that reaches the end of the slinkywill be more visible for comparison. Extend each slinky about 3 m and cause P or S waves to be
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generated simultaneously in both slinkys by hitting the wood block (for P waves) or quickly movingthe wood block vertically or horizontally (for S waves). The regular slinky will propagate the wavesvery efficiently while the slinky with the foam will strongly attenuate the wave energy (by absorbingsome of the energy) as it propagates.
Reflection of Waves: The reflection of wave energy at a boundary between two types of materialscan be demonstrated with slinkys by attaching a regular metal slinky to a plastic slinky (Figure 24).The attachment can be made with small pieces of plastic electrical tape. Generating P or S waves inthe metal slinky will result in reflection of some of the wave energy at the boundary between the twostretched slinkys. Additional information about reflection and conversion of energy (S to P and P toS waves) of seismic waves at boundaries is given in Figure 25 and in Bolt (1993, p. 31-33)
Figure 24. Two slinkys a metal slinky and a plastic slinky attached together using small pieces of
electrical tape. The two slinkys can be used to illustrate reflection and transmission of wave energy
at a boundary between elastic materials with differing elastic properties.
IncidentRaypath
Refracted
Refle
cted
Interface
Reflection and refraction of P or Sraypaths (and associated wavefronts
wh ich are perpendicular to raypaths)
i i
r
Veloci ty 1
Velocity 2
Figure 25. Reflection and refraction (transmission) of seismic
waves (P or S waves) at an interface separating two different
materials. Some energy is reflected and some is transmitted.
The effect can be illustrated with two slinkys one metal and
one plastic taped together. Waves traveling along one slinky
are partially reflected at the boundary between the two types of
slinkys. For seismic waves in the Earth, an incident P or S
wave also results in converted S and P energy in both the upper
material (reflected) and the lower material (transmitted). If the
angle of approach of the wave (measured by the angle of
incidence, i, or the associated raypath) is not zero, the resulting
transmitted P and S raypaths will be bent or refracted at theboundary. A similar change in angle is also evident for the
reflected, converted waves.
Surface Waves:The Love wave (Figure 12; Table 2) is easy to demonstrate with a slinky or a doublelength slinky. Stretch the slinky out on the floor or on a tabletop and have one person at each end
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hold on to the end of the slinky. Generate the Love wave motion by quickly moving one end of theslinky to the left and then to the right. The horizontal shearing motion will propagate along theslinky. Below the surface, the Love wave motion is the same except that the amplitudes decreasewith depth (Table 2). Using the slinky for the Rayleigh wave (Figure 11, Table 2) is much moredifficult. With a regular slinky suspended between two people, one person can generate the motionof the Rayleigh wave by rapidly moving his or her hand in a circular or elliptical motion. The motionshould be up, back (toward the person generating the motion), down, and then forward (away fromthe person), coming back to the original location and forming an ellipse or circle with the motion ofthe hand. This complex pattern will propagate along the slinky but will look very similar to an Swave (compare Figures 10 and 11). Excellent illustrations of the wave motion of Love and Rayleighwaves can also be found in Bolt (1993, p. 37). Rayleigh wave motion also decreases with depthbelow the surface. Further details on the characteristics and propagation of Love and Rayleigh wavescan be found in Bolt (1993, p. 37-41).
Oscillations of the Whole Earth: When a very large earthquake occurs, long period surface waveenergy penetrates deep within the Earth and propagates all around the globe. At particular points
around the globe, the timing between this wave energy (which just keeps circling the globe for manyhours or even days before dying out or attenuating) results in constructive and destructiveinterference of the wave energy. The resulting oscillations at certain frequencies are called normalmodes or free oscillations of the Earth and are vibrations of the whole Earth. Further informationabout Earth normal modes, the phenomenon of standing waves, and diagrams illustrating the modesof vibration of the whole Earth are available in Bolt (1993, p. 34-37 and 144-145) and Shearer (1999,p. 158-162).
Seismic Waves in the Earth: Seismic body waves (P and S waves) travel through the interior of theEarth. Because confining pressure increases with depth in the Earth, the velocity of seismic waves
generally increases with depth causing raypaths of body waves to be curved (Figure 26). Because theinterior structure of the Earth is complex and because there are four types of seismic waves(including dispersive surface waves), seismograms, which record ground motion from seismic wavespropagating outward from an earthquake (or other) source, are often complicated and have long(several minutes or more) duration (Figures 27 and 28). An effective computer simulation thatillustrates wave propagation in the Earth is the program Seismic Waves (Figure 29) by Alan Jones(see reference list). Using this program, which shows waves propagating through the interior of theEarth in speeded-up-real-time, one can view the spreading out of wavefronts, P, S, and surface wavestraveling at different velocities, wave reflection and P-to-S and S-to-P wave conversion. Theprogram also displays actual seismograms that contain arrivals for these wave types and phases.Exploring wave propagation through the Earth with the Seismic Waves program is an excellent
follow-up activity to the seismic wave activities presented in this teaching guide.
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Radiu
s=6371
km
Rad
ius
=633
6km
Radius
=
3486km
Ra
di
us=
121
6km
Outer Core
Inner
Core
Mantle
Earthquake
Crust (thickness
exaggerated)
P and S
raypaths
Distancealong
surface(km
)
Angular Distance(degrees) Seismo-
graph
P,SS
PP
SurfaceWaves
P
S
pP
PcP
PKP
Figure 26. Cross section through the Earth showing important layers and representative raypaths of
seismic body waves. Direct P and S raypaths (phases), including a reflection (PP and pP), converted
phase (PS), and a phase that travels through both the mantle and the core (PKP). P raypaths are
shown by heavy lines. S raypaths are indicated by light lines. Additional information about raypaths
for seismic waves in the whole Earth and illustrations of representative raypaths are available in
Bolt (1993, p. 128-142) and Shearer (1999, p. 49-60). Surface wave propagation (Rayleigh waves
and Love waves) is schematically represented by the heavy wiggly line. Surface waves propagate
away from the epicenter, primarily near the surface and the amplitudes of surface wave particle
motion decrease with depth.
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Figure 27. Seismograms recorded by a 3-component seismograph at Nana, Peru for an earthquake
located near the coast of central Chile on September 3, 1998. The three seismograms record motion
in the horizontal (east-west and north-south) and the vertical (Z) directions. P, S, Rayleigh and Love
waves are identified on the record. The S wave arrives significantly after the P-wave because S-wavevelocity in rocks is lower than P wave velocity. Additional arrivals between the P and the S wave are
P and S waves that have traveled more complicated paths (such as the pP and PP phases and P-to-S
converted phases, Figure 26) from the earthquake location to the seismograph. The surface waves
arrive after the S waves because surface wave velocities in rocks are lower than the shear wave
velocity. The surface waves extend over a long time interval because surface wave propagation is
dispersive (the velocity of propagation is dependent on the frequency of the wave). This dispersive
character can easily be seen in the Rayleigh wave on the vertical (Z) component seismogram in that
the earliest Rayleigh wave energy has a longer period (lower frequency; see Figure 1) than the later
arriving waves. The seismic data that are displayed here were acquired from the IRIS website
(www.iris.edu) using the WILBER program from the IRIS Data Management Center.
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Figure 28. Model of the Earth's interior and selected raypaths for seismic wave propagation from
the 1994 Northridge earthquake to seismograph stations around the world. Because of the existence
of several types of seismic waves and the complex structure of the Earth's interior, many arrivals
(phases) of seismic energy are present and are identified on the seismograms. This figure is part of a
poster (Hennet and Braile, 1998) that is available from IRIS.
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Figure 29. Partial screen views of the Seismic Waves computer program. The upper image shows
seismic wavefronts traveling through the Earth's interior five minutes after the earthquake. Thelower image shows the wavefronts 7 minutes after the earthquake. P waves are shown in red; S
waves are shown in blue; and Surface waves are shown in yellow. Three and four letter labels on the
Earth's surface show relative locations of seismograph stations that recorded seismic waves
corresponding to the wavefront representations in the Seismic Waves program.
The Slinky: The slinky was invented in 1943 and over 250 million of them have been sold. Thehistory of the slinky, including its invention and the information about the company thatmanufactures the slinky, can be found at the discovery and slinkytoys internet addresses in thereference list. Slinkys (Figure 30), including the original metal slinky, the plastic slinky, slinkyjunior, several "designer" slinkys made from a variety of metals, and slinky toys can be found at the
slinkytoys internet address listed in the reference list. Both the original metal slinky and plasticslinkys are usually available (for about $2) at discount department stores such as K-Mart, Wal-Martand Target. A "long" slinky can be ordered, but can also be made by taping together two regularslinkys with small pieces of plastic electrical tape to make a double-length slinky. The original metalslinky is the most effective type of slinky for most of the wave propagation activities. A double-length slinky is useful for illustrating Love wave motion (and the concept of standing waves) on the
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floor. The plastic slinky does not propagate compressional or shear waves as efficiently as the metalslinky, but is useful for illustrating reflection and transmission of wave energy at a boundary betweentwo elastic materials with different properties. For this demonstration, tape a metal slinky and aplastic slinky together by attaching the end coils with small pieces of plastic electrical tape.
Figure 30. Slinkys. A. Original metal slinky; B. Plastic slinky; C. Long slinky; D. Slinky junior.
Slinky lessons for teaching, including physics and wave activities, can be found at theNewtons(fromthe Newton's Apple PBS television program), and the teachingtools and eecs.umich (NationalEngineers Week activities) internet addresses. The National Engineers Week slinky activities areassociated with a video ("Slinky Science Shindig") that is available from the eweek.orgaddress.
Slinkys are educational and fun! It is useful to have many of them available for the activitiesdescribed in this teachers guide and for your students to perform the activities, and to experiment anddiscover.
Summary:The slinky in various forms provides an excellent model to demonstrate and investigateseismic wave characteristics and propagation. A summary of the slinky models and their uses indemonstrations and activities is given in Table 3. Additional information on seismic waves, wavepropagation, earthquakes and the interior of the Earth can be found in Bolt (1993, 1999 and 2004).Illustrations of seismic wave propagation through the Earth and seismograms are contained in Bolt(1993, 1999 and 2004) and Hennet and Braile (1998).
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Table 3: Slinky Types, Models and Demonstrations
Number Slinky Types/Models Demonstrations Figure
Number
1 Regular metal slinky P and S waves 13, 14
2 Long slinky (or attach 2 regularslinkys together with plastic
electrical tape)
Love wave on floor or tabletop ---
3 Slinky with cardboardbuilding
Illustrate that P and S energy ispropagating and causes the cardboard
building to shake as wave arrives.Differences in shaking can be seen
for P and S motion
15, 16
4 Two slinkys (plastic and metal)attached with plastic electrical
tape
Reflection and transmission of energyat a boundary between materials ofdifferent types (elastic properties or
seismic velocities)
24, 25
5 Five slinkys attached to woodblock
Show that waves propagate in alldirections from source; that travel
time is different to differentdistances; and that wave vibration forP and S sources will be different indifferent directions from the source
17, 18,19
6 Two slinkys attached to woodblock, one with soft foam within
the coils; cardboard buildingscan be attached to the slinkys to
help see the differences inshaking
Illustrate the concept of attenuationdue to absorption of energy during
propagation and that some materialspropagate waves more efficiently
than other materials
22, 23
Notes to the Teacher: The activities described in this teachers guide are designed for bothclassroom demonstration and inquiry-based activities for students. The elastic properties of a springand the waves in a water tank activities are appropriate for student experiments. Several of the slinky
activities and the human wave demonstration actively involve students in the class. The slinkydemos should also be performed by the students to increase their understanding of the wavepropagation characteristics and concepts. All of the activities provide opportunities for developingand practicing observation skills and experience with measuring and timing. These demonstrationsand activities are suitable for inclusion in Earth science teaching at a variety of levels. At highergrade levels, more complete treatment, increased emphasis on necessary vocabulary (defining the
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properties of elasticity, describing the characteristics of motion of the different types of seismicwaves, etc.), involving quantitative measurements (measuring and graphing the elasticity of a spring,calculating the velocity of propagation of waves, etc.), and connection to related seismology andother Earth science lessons and activities are desirable.
The depth of investigation and the length of time devoted to the seismic wave activities will dependon the grade level and characteristics of the students, time available, and teacher preference. Theteacher will also need to determine the "degree of constructivism" to be employed in the teachingstrategy for these demonstrations and activities. For example, several of the activities, such as the P-and S-wave propagation in a slinky, could be performed first as a demonstration and then by thestudents to develop further understanding by first-hand experience. Alternatively, the teacher couldchoose to have a brief classroom discussion about P and S waves and then challenge the students touse the slinky to discover P- and S-wave propagation and determine the primary characteristics of thewaves (property of propagation, material returns to original condition after the wave has passed,reflection of wave energy, particle motion) and the distinctive differences between P and S waves.This student exploration would then be followed by a "final" demonstration to emphasize the key
concepts and clarify any misunderstandings. The seismic wave activities should normally beincluded in an earthquake unit of an Earth science curriculum that also covers plate tectonics and thecauses of earthquakes, Earth's interior structure, seismographs and seismograms, earthquake locationmethods, and earthquake hazards.
Appropriate assessment methods for the activities and science content presented here can includeboth written and oral responses by students and specific assessment activities. The scope and depthof questioning will depend on class level, time devoted to the seismic wave activities and how muchrelated Earth science material (such as studies of plate tectonics, earthquake statistics and hazards,Earth structure, etc.) has been covered. If student teams have completed the elasticity of a spring,waves in water, and/or velocity of propagation experiments, the teacher will have some written
material from the results of the student's experiments that can be assessed.
Here are some suggested activities that can be used for authentic assessment: (1) Have studentsperform the P and S wave slinky demonstrations and describe their observations and the wavecharacteristics that they observe. (2) Have students repeat the elasticity experiment with a spring thathas a different spring constant (a "weaker" or "stronger" spring). Have students predict what thegraphed line will look like in comparison with their previous result, then perform the experiment andgraph the results. Their predictions should be close to the actual results. (3) Ask students to predictwhat would happen if a rubber band was used instead of the spring in the elasticity experiment (theyshould describe the expected result in terms of the two main properties of elasticity). (4) Provide thestudents with a graph showing a hypothetical seismic wave. Have the students interpret the graph
and identify principal wave characteristics (frequency, amplitude, peaks, etc.). (5) Provide thestudents with copies of unlabeled diagrams illustrating the four types of seismic waves (lower threegrids of the perspective views of P, S, Rayleigh and Love wave propagation in Figures 9-12 or fromBolt (1993, p. 27 and p. 37; remove labels identifying wave type). Have the students identify whichdiagram corresponds to the four types of seismic waves and what characteristics of the wave motionallow them to identify the wave type. (6) Obtain the Seismic Waves computer program and
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demonstrate to the students or provide the students with the opportunity to run the program. Next,with the program available on a monitor, start waves propagating (pause or restart as necessary) forone of the earthquakes and have the students watch the wavefront diagram (interior of Earth; it isconvenient to set the display to view only the Earth cross section view; use the "Options" menu and"Select View " to choose the cross section view) and have them answer the following questions.What are the approximate shapes of the initial (in the upper mantle near the source) P and Swavefronts? Why are they shaped that way? From the P and S wavefronts, estimate the relativevelocity of the S wave as compared to the P wave (for example, how much longer does it take for theS wave to arrive at a station or to travel from the source to the core-mantle boundary as compared tothe P wave)? How long does it take for the P wave to travel directly through the Earth to the oppositeside of the Earth from the source? This distance (the diameter of the Earth) is about 12,742 km.From these measurements, what is the approximate average velocity for P waves in the Earth (inkm/s)? Explain the new wavefronts that are generated when the P or S wave hits the core-mantleboundary. Why is there no S wave that travels directly through the Earth to the other side? Can therebe S waves in the inner core (the program may not be of much help here except to visualizewavefronts that propagate in the Earth's core because no S wave phases from the inner core are
displayed; not all seismic phases or raypaths are illustrated by the program)? How could S waves begenerated so that they would travel through the inner core? Open the whole Earth view (surface ofEarth with oceans and continents is visible). How are the patterns of the wavefronts that you seepropagating and expanding from the source similar to the water waves in the wave tank experiment(or generated by a pebble dropped into a mud puddle or a pond)? How are they different?
Below are some suggested questions for a written assessment. (1) What is the source of energy forthe generation of seismic waves; in the slinky demonstrations? in the Earth? (2) How could wedemonstrate that energy is carried by the waves in the slinky demonstrations? (3) How can wedetermine the velocity of propagation of a wave? (4) Explain the property of elasticity. (5) Explainhow the slow motions of the Earth's plates (like slowly deforming the stretched slinky in the P and S
demonstrations alternative methods of wave generation) can produce a rapid release of energy (slipalong a fault in an earthquake, release of stored elastic energy in the slinky) resulting in seismicwaves propagating in the Earth (or the slinky).
The activities and the science content contained in this teachers guide have significant connections tothe National Science Education Standards (NSES; National Research Council, 1996;http://www.nap.edu/readingroom/books/nses/html/) as detailed in Table 4.
Additional related activities can be found at: http://web.ics.purdue.edu/~braile/. A simplified, fourpage version of this document can be found at:http://web.ics.purdue.edu/~braile/edumod/slinky/slinky4.htm. MS Word and pdf versions of these
materials (easier for printing) can be found at:http://web.ics.purdue.edu/~braile/edumod/slinky/slinky.dochttp://web.ics.purdue.edu/~braile/edumod/slinky/slinky.pdfhttp://web.ics.purdue.edu/~braile/edumod/slinky/slinky4.dochttp://web.ics.purdue.edu/~braile/edumod/slinky/slinky4.pdf.
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Table 4. "Seismic Waves and the Slinky: A Guide for Teachers" and the National Science Education
Standards (NSES;http://www.nap.edu/readingroom/books/nses/html/).
NSES Standard How standard is addressed by Seismic Waves and theSlinky demonstrations, lessons and activities*
Science Teaching Standards Many of the activities are inquiry-based (A, B) and provideopportunities for ongoing assessment (C).
Professional Development Standards The guide for teachers provides opportunities and appropriateresource material for teachers to learn about an Earth sciencetopic that is not likely to have been included in their previouseducational experiences (A, C) and includes suggestions foreffective teaching strategies (B).
Assessment Standards Authentic assessment activities and questions for assessingachievement in learning key concepts are included (C).
Science Content Standards
- Unifying Concepts and Processesin Science
Activities provide experience with observation, evidence andexplanation, and constancy, change and measurement.
- Science as Inquiry Activities provide opportunities for practice of inquiry and offundamental science skills (Grades 5-8 and 9-12, A).
- Physical Science Standards Activities explore properties and changes of properties inmatter, motion and forces, transfer of energy (Grades 5-8, B).
Activities explore structure and properties of matter, motionsand forces, and interactions of energy and matter (Grades 9-12, B).
- Earth and Space Science Activities explore structure of the Earth system (Grades 5-8,D).
Activities relate to energy in the Earth system (Grades 9-12,D).
- Science in Personal and SocialPerspectives
Activities explore natural hazards (Grades 5-8, F).
Activities explore natural and human-induced hazards(Grades 9-12, F).
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Table 4. (continued)
Science Education Program Standards Seismic wave activities are developmentallyappropriate, interesting and relevant, and emphasize
student understanding through inquiry, and areconnected to other school subjects (B).
Seismic wave activities provide practice withmathematics and analysis skills (C).
Activities provide experience with a variety ofmaterials and resources for experimentation and directinvestigation of phenomena (D).
Science Education System Standards Because only relatively simple and inexpensiveresources are necessary to perform the seismic wave
demonstrations and activities, they are easily accessibleto all students.
*Letters in parentheses identify specific standards within the six areas (Science Teaching,
Professional Development, Assessment, Science Content, Science Education Programs, and Science
Education System Standards) of the NSES.
References:
Bolt, B.A., Earthquakes and Geological Discovery, Scientific American Library, W.H. Freeman,New York, 229 pp., 1993.
Bolt, B.A.,Earthquakes, (4th
edition), W.H. Freeman & Company, New York, 364 pp., 1999.
Bolt, B.A.,Earthquakes, (5thedition; similar material is included in earlier editions), W.H. Freeman& Company, New York, 378 pp., 2004.
Earthquake, NOVA series videotape, 58 minutes, available from 800-255-9424; http://www.pbs.org,1990.
Hennet, C., and L.W. Braile,Exploring the Earth Using Seismology Color Poster, The IRISConsortium, Washington, DC., www.iris.edu, 1998.
IRIS website, http://www.iris.edu.
Jones, Alan, Seismic Waves, Computer program for visualizing seismic wave propagation throughthe Earth's interior, download from: http://www.geol.binghamton.edu/faculty/jones.
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Seismic Waves and the Slinky Teachers Guide Page 36 of 36
Living with Violent Earth: We Live on Somewhat Shaky Ground, Assignment Discovery seriesvideotape, Discovery Channel, 25 minutes, http://www.dsc.discovery.com, 1989.
National Research Council,National Science Education Standards, National Academy of Sciences,Washington, D.C., 262 pp., 1996; also at: http://www.nap.edu/readingroom/books/nses/html/.
Rutherford, B., and S. A. Bachmeyer,Earthquake Engineering The Epicenter Project Book, Pitsco,Inc., Pittsburg, Kansas, 24 pp., http://www.pitsco.com/, 1995.
Seismology Resources for Teachers,http://web.ics.purdue.edu/~braile/edumod/seisres/seisresweb.htm, a list of seismology-relatedreference materials for education.
Shearer, P. M.,Introduction to Seismology, Cambridge University Press, Cambridge, UK, 260pp,1999.
Slinky websites:http://www.discovery.com/stories/history/toys/SLINKY/shoulda.htmlhttp://www.slinkytoys.com/main.htmhttp://www.tpt.org/newtons/9/slink.htmlhttp://www.teachingtools.com/SlinkyShindig/slinky.html
http://www.eecs.umich.edu/~coalitn/sciedoutreach/funexperiments/quickndirty/eweek/slinky.htmlhttp://www.eweek.org/1999/Forms/disce.html#slinky
Zubrowski, B.,Making Waves, Beech Tree Books, New York, New York, 96 pp, 1994.
Copyright 2000-2006. L. Braile. Permission granted for reproduction for non-commercial uses.
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